This invention relates to image management systems, and more particularly to image reconstruction on an image workstation coupled to an image manager.
BACKGROUND OF THE INVENTION
Medical scanners and medical imaging machines are an integral part of modern medical practice. These scanners and medical imaging devices utilize both electromagnetic radiation and sonic wave to produce images which are viewed by doctors for the diagnosis and care of patients. For example, ultrasound machines are useful for viewing fetuses during prenatal care in a pregnancy or blood flow patterns in arteries. Magnetic resonance imaging (MRI) machines are useful for producing images of a wide range of soft tissues.
In a large hospital, medical scanners and medical imaging devices are preferably networked with a central image management system, such as a picture archival and communications system (PACS). The PACS is designed to provide a central storage for archive for medical images. Further, PACS is configured so that stored images may be retrieved. Typically, a hospital will have a single PACS that is networked with a plurality of medical scanners and medical imaging devices located throughout the hospital. Further, the PACS will be networked with a plurality of image workstations, such as a PACS workstation. Images generated by medical scanners and medical imaging devices are transferred to the PACS for storage and later retrieval and review by doctors located throughout the hospital at any of the plurality of image workstations.
Conventionally, doctors or users of image workstations (e.g., PACS workstations) were able to view only two dimensional image renderings of the images retrieved from the PACS. Three dimensional image rendering was restricted to three dimensional rendering on stand alone workstations dedicated for three dimensional graphics processing. Further, because of the restriction to stand alone workstations, conventional three dimensional graphics processing was not carried out on PACS workstation therefore image information and data could not be simply received from the PACS server. Further, because the 3D processing is conventionally carried out on stand alone workstations, the PACS has not been used to store 3D image information.
Therefore, there is a need for an image workstation that is in communication with the PACS server and is configured to carry out 3D processing thereon. Further, there is a need for an image workstation that is capable of receiving image information from the PACS server and constructing a 3D image rendering, and communicating the 3D image rendering (or 3D image rendering parameters) to the PACS server for storage and later retrieval.
SUMMARY OF THE INVENTION
A preferred embodiment of the invention relates to an image management system. The image management system includes an image manager having a plurality of inputs and outputs. The inputs are configured to receive image information signals and the outputs configured to provide image output signals. The image manager is configured to store information representative of a plurality of two dimensional image slices and the output signals are representative of the stored two dimensional image slices. The image management system also includes an imaging device having an output coupled to at least one of the inputs of the image manager and is configured to provide an image signal. The image management system further includes an image workstation having an input coupled to at least one of the outputs of the image manager and is configured to receive output signals from the image manager representative of selected two dimensional image slices stored by the image manager. The image workstation is configured to construct three dimensional image renderings from the two dimensional image slices. The image workstation has an output coupled to the image manager. The image workstation is configured to provide the image manager with a signal representative of the three dimensional rendering.
Another embodiment of the invention relates to a method of producing a rendering of a three dimensional object from a plurality of two dimensional image information files. The method includes receiving, by an image manager, a plurality of two dimensional image information files from an imaging device and storing a plurality of two dimensional image files on the image manager. The method also includes communicating selected two dimensional image information files to an image workstation and receiving a two dimensional image information file by the image workstation. The method further includes constructing a three dimensional image file based on the two dimensional image information files and communicating the three dimensional image information file to the image manager.
Yet another embodiment of the invention relates to a medical imaging system. The medical imaging system includes a medical scanner and an image manager coupled to the medical scanner and configured to receive and store signals representative of two dimensional image slices from the medical scanner. The medical imaging system includes an image workstation configured to receive selected signals representative of two dimensional image slices and configured to construct a three dimensional rendering file from the signals representative of the two dimensional image slices. The three dimensional rendering file is communicated to and stored by the image manager.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will become more fully understood from the following detailed description, taken in conjunction with the accompanying drawings, wherein like reference numerals refer to like parts, in which:
FIG. 1 is a block diagram of an image handling system; and
FIG. 2 is a block diagram of data flow from a scanning or imaging device to an imaging workstation.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring now to FIG. 1, a block diagram of an image handling system 10 is depicted. Image handling system 10 includes an image manager 20 which, in a preferred embodiment, is a picture archival and communication system (PACS) server, however image manager 20 is not limited to a PACS server, but may be any picture archiving apparatus. In a preferred embodiment, image manager 20 includes an information storage unit (ISU) for short-term storage and retrieval and an archival storage unit (e.g., an optical disc storage and optical disc reader system) for long-term storage and retrieval.
Image manager 20 is coupled to a plurality of imaging devices 30 which are configured to create digitized image information based on an image subject such as, but not limited to, portions of the human anatomy. In a preferred embodiment, imaging devices 30 include, but are not limited to magnetic resonance imaging (MRI) devices, ultrasound imaging devices, computed tomography (CT) devices, nuclear imaging devices, X-ray imaging devices and any other types of imaging devices, not limited to the medical field. In a preferred embodiment, imaging devices 30 produce image files in the DICOM3 or DEFF formats however, other image file formats are equally applicable. The image files are communicated from imaging devices 30 to image manager 20 as two dimensional slices or image information representative of two dimensional slices through the object being imaged. Therefore, from a single image file stored on image manager 20, a two dimensional image rendering may be reconstructed. Such two dimensional renderings are often presented to a user on any of a number of workstations 40 that are coupled to communications network 22 (such as an ethernet or other applicable communications network connection) that is in communication with image manager 20. Workstation 40 may be, in a preferred embodiment, a PACS workstation.
In a preferred embodiment, it is preferable to have the option of viewing the imaged object in a three dimensional rendering on workstation 40 instead of a two dimensional rendering. Three dimensional renderings may be accomplished by a number of pertinent algorithms including surface rendering algorithms, maximum intensity projections (MIP) and other applicable three dimensional rendering processes. Referring now to FIG. 2, a block diagram, showing a portion of system 10, depicts the flow of information in system 10. In operation, scanner 30 scans an object, such as a patient. Scanner 30 generates an electrical signal representative of the configuration of the object. The analog signal is communicated to a digital analog converter 35. Digital analog converter 35 produces a digital signal that is communicated to PACS server or image manager 20. In an alternative embodiment, scanner 30 may directly generate a digital signal, thus digital to analog converter 35 would not be required. Further, alternatively scanner 30 may include the digital analog converter 35 therein. Image manager 20 stores the image signals in a file format such as DICOM3 or DEFF. The image files may be stored on any of a variety of storage devices, such as magnetic storage devices or optical storage devices. Image information from image manager 20 may be selectively retrieved by any of a number of workstations or other information retrieval devices coupled to communications network 22. Workstation 40 includes a display device 45.
To display a three dimensional image on display 45, workstation 40 may retrieve a plurality of two dimensional image files from image manager 20. However, in a preferred embodiment, workstation 40 includes programmed logic or software that allows display 45 to show a three dimensional image rendering that is generated on workstation 40. Further, in a preferred embodiment, the three dimensional image rendering (or parameters used to reconstruct the three dimensional image rendering) may be stored on the PACS workstation in a three dimensional image rendering file. The three dimensional rendering file may be communicated to and stored on the PACS server or image manager 20.
Therefore, a user working at a workstation 40 may retrieve three dimensional image rendering files that are stored on the PACS workstation 40 and have previously been generated on PACS workstation 40. The physician may manipulate (rotate, scale, colorize, measure, etc.) and view the three dimensional rendering, retrieved from the PACS workstation, that were previously generated by the PACS workstation and subsequently stored on the PACS workstation.
While the preferred embodiment refers to imaging devices used in the medical area, the reference to imaging devices may be interpreted broadly. The embodiment can encompass those situations in which any imaging device is coupled to and in communication with a communications network and an image manager.
Further, those who have skill in the art will recognize that the present invention is applicable with many different hardware configurations, software architectures, communications protocols and organizations or processes.
While the detailed drawings, specific examples, and particular formulations given describe preferred embodiments, they serve the purpose of illustration only. The materials and configurations shown and described may differ depending on the chosen performance characteristics and physical characteristics of the communications networks.
For example, the type of communications network or communications protocols used may differ. The systems shown and described are not limited to the precise details and conditions disclosed. Furthermore, other substitutions, modifications, changes, and omissions may be made in the design, operating conditions, and arrangements of the preferred embodiments without departing from the spirit of the invention as expressed in the appended claims.